DE102005041990A1 - Alarm system - Google Patents

Abstract

The invention relates to a hazard alarm system 1 with a function module 2 functioning as a control center and with at least one detector 3 which is remote from the control center. The control unit 3 is supplied with energy by the control center in a wireless manner.

Description

The The invention relates to a hazard alarm system according to the preamble of Claim 1. Hazard detection systems, such as intruder alarms and fire alarm systems, are systems that are generally a central, as well as connected to this center detectors include. The local of The central remote detectors are information technology over a Radio link connected to the control panel. In case of a change of state, those from a monitored by the detector Area is reported to the central office, a corresponding Data stream transmitted to the central office. In the idle state, the connection between the detector and the Central monitored by transmitting a cyclic idle stream. That remains Data signal longer as a predefinable time, this is as a fault and / or sabotage message rated. This monitoring is in many cases an admission requirement for Alarm systems. The required monitoring frequency can be up to once per 10 seconds (EN class 4 systems). The detectors connected by radio to the control panel can also with one independent from the central office Be equipped with energy supply. The power supply takes place for example about the detector associated batteries or mains powered power units. Both batteries and mains powered power units but build very tall, which stands in the way of miniaturization of the detectors. To detectors as possible inconspicuous and To be able to install space-saving, however, further miniaturization is required. Although was already tried to get along with smaller batteries. These can, however comparatively little energy for provide the supply of the detector. This results in regularly monitored Detectors for a short service life and requires a high Service effort.

Out DE 37 15 196 A1 a security alarm system with a plurality of detectors connected to one or more two-wire loop lines is known in which a line module is provided for each detector, which is provided with a control device. In the line module, a switching means is present, which is initially open when commissioning the alarm system. The first line module connected to the central office receives an address from the central office, which is stored in the control device, and then the command for closing the switching means. In this way, successively all line modules to which the detectors are connected, provided with addresses, which they can be selectively controlled by the control panel and receive commands and send messages to the headquarters.

Out DE 197 23 737 A1 a ring bus system is known with a central office, which are connected to a ring closed data lines, in which bus components are looped. A supply line for the bus components has a fuse for the downstream bus components in a conductor. Electrically parallel to the conductor and the fuse, another conductor with fuse is routed to the bus components. The bus components are connected to both conductors via decoupling diodes. If a short circuit occurs in one part of the voltage-carrying cable ring, the corresponding fuse of the partial ring is destroyed, but the remaining partial ring, because decoupled via diodes, continue to supply the bus components with voltage.

Out DE 102 04 138 A1 a communication device is known which has a transmitter and / or receiver which has a signal coupling to an energy store for sending and / or receiving a radio signal. The energy store is preferably designed as a battery. The battery can also be an element of a magnetic loop antenna. Preferably, the communication device is used in a detector. In this document, although it is proposed to use an existing energy storage device in the communication device, such as a battery or a rechargeable battery, as an antenna. However, a charge of the energy storage device via a radio link is not mentioned.

Advantages of invention

The alarm system according to the invention with the features of claim 1 allows despite further miniaturization of the detectors a very reliable operation of the hazard detection system, as always enough energy is available to regularly monitor the detectors in relatively short time intervals. The invention makes use of the wireless transmission of the energy required for the operation of the detector from the center. The security alarm system according to the invention provides largely miniaturized detectors without autonomous power supply to the objects to be monitored (eg doors, windows, works of art or the like). That is, the individual detectors are equipped in an advantageous embodiment of the invention neither with a large-sized battery nor connected to a mains-powered power supply device. Since the detector has no batteries, eliminating the high service costs for changing the battery. At the same time a strong miniaturization of the detectors is possible. The very small detectors can be installed very inconspicuously. The condition of the detector is in, in known manner, queried by radio by appropriate query data from the control center to the detector and corresponding response data are transmitted from the detector to the control center. The polling frequency can be greatly increased since no limitation on the part of the energy supply is to be feared. This in turn benefits the operational safety of the alarm system, as there is always a precise overview of the status of the detector. This advantage is achieved in that the energy required for the supply of the detector is also transmitted wirelessly, namely from the center of the alarm system. For this purpose, the detector comprises, in addition to the transmitting and receiving antenna, an energy converter, possibly a storage device for energy, a logic module, a coding module and at least one sensor element. If the object secured by the security alarm system has a greater extent, according to an advantageous further embodiment of the invention, between the control center and the detector, or a group of detectors, additionally a function module is switched that for the connection of the detector or the detector to the center responsible is. Advantageously, for each monitoring unit of the object divided into monitoring units, for example for each room of a building to be monitored, such a functional module is provided which communicates with a plurality of detectors in the respective room. The connection between the functional module and the control center is expediently carried out via a wired data bus or alternatively also via a wireless communication channel. The connection between the individual detectors and the function module is again wirelessly via a radio link.

drawing

embodiments The invention will be described below with reference to the drawing explained in more detail. there shows

1 a schematic block diagram of a hazard alarm system;

2 the block diagram of a detector.

description the embodiments

1 shows a schematic block diagram of a hazard detection system 1 , Based on this 1 Below are two variants of the hazard alarm system 1 explained. In a first embodiment, the danger detection system comprises 1 a functional module 2 , as the headquarters of the security system 1 serves. The functional module 2 includes a functional module 2.5 that supplies the power to at least the functional module 2 ensures. Preferably, the functional module 2.5 connected to the mains. Furthermore, the functional module comprises 2 a functional module 2.1 That's for communicating with a detector 3 is provided. The in the block diagram according to 1 displayed detector 3 Of course, here represents a larger number of detectors. The functional module 2.1 is a transceiver via a communication channel 2.3 with the detector 3 connected is. In the embodiment described herein, the communication channel is 2.3 to a bidirectional radio transmission link. The detector 3 includes a functional module 3.2 and a functional module 3.3 , as well as at least one sensor 3.1 , The functional module 3.3 is a transceiver over the communication channel 2.3 with the function module 2 communicates. The functional module 3.3 has an antenna 20 for broadcast and reception ( 2 ). The functional module 3.2 is an encoding unit, with which between the function module 2 and the functional module 3 exchanged signals can be encoded or decoded. A corresponding function module 2.7 is also in the function module 2 arranged. At the sensor 3.1 it is, for example, a contact, in particular magnetic contact, with two operating states, namely open or closed. According to the invention, the detector has 3 does not have an autonomous power supply but is via the communication channel 2.3 , ie by radio, from the function module 2 energized. These are to the antenna 20 of the function module 3.3 two functional modules 22 . 23 connected. The functional module 22 is with a storage device 21 connected, which is drawn here lying outside the function module, but also in the function module 3.3 itself can be arranged. In this storage device 21 it is advantageous to a capacitor or an accumulator in the smallest possible design with comparatively low capacity. The functional module 23 is with the functional module 3.2 connected.

In the following, the operation of this embodiment of the invention will be described. The focus will be on the invention designed according to the power supply of the detector 3 placed while the data transfer between the detector 3 and the functional module 2 only briefly touched. To the detector 3 to power is provided by the transceiver 2.1 of the function module 2 generates an electromagnetic field in an allowable frequency range of the electromagnetic spectrum. About the antenna 20 of the functional module provided in the detector 3.3 energy is removed from the electromagnetic field. The functional module 22 converts the recorded RF voltage into a DC voltage around, with the memory device 21 is charged. The energy stored there now stands for the supply of the detector 3 to disposal. It stands for the charging of the memory device 21 various design variants available. According to a first embodiment, that of the functional module 2.1 provided electromagnetic field can be constantly maintained. This is not particularly energy efficient, but offers the advantage of being the detector 3 always on a fully loaded storage device 21 can fall back. According to a more complex embodiment variant are in the detector 3 Means for polling the state of charge of the memory device 21 intended. Once the storage device 21 is fully charged, via the communication channel 2.3 a corresponding signal to the function module 2 transmitted, which leads to a temporary shutdown of the electromagnetic field. In addition, a second threshold for the state of charge may be provided, below which the electromagnetic field is reactivated. According to a third embodiment, the electromagnetic field is only in connection with a query of the detector 3 , for example, only shortly before a query of the detector 3 , switched on. When asked by the detector 3 is the current switching state of the in the detector 3 built-in sensor 3.1 queried and the detected state of the sensor 3.1 to the function module 2 transfer. Should the detector 3 If this query is not available, this will be done by the function module 2 interpreted as an alarm situation. This alarm situation can be caused by a fault, a defect or sabotage. An alternative embodiment of the query of the detector 3 is realized by the detector 3 a resonant component, for example a SAW element based on acoustic harmonics, which is connected to the antenna 20 connected is. The resonant component reflects the received radio-frequency energy and modulates it in such a way that the functional module 2 on the identity of the detector 3 and its state can close. Such a modulation can be realized, for example, by the generation of characteristic pulse sequences in the time domain.

At a larger extent of one of the hazard alarm system 1 object to be monitored and greater distances between the functional module 2 and detectors 3 is an advantageous further embodiment of the invention preferable. This embodiment is also with reference to 1 and 2 explained. This variant additionally comprises a functional module 4 that works between the function module 2 and the detector 3 is switched. For example, in addition to at least one functional module functioning as a central office 2 , several functional modules 4 be provided. It is advantageous in each case a functional module 4 each assigned to a monitoring unit of an object, for example, each room of a building. Every functional module 4 in turn, can have a larger number of detectors 3 be assigned. In terms of data, this is the function module 4 via a wired data bus 2.2 or a wireless communication channel 2.4 , such as a radio link, with the functional module 2 connected. To a radio connection with the function module 2 to enable, includes the functional module 4 advantageously a functional module 4.1 , which serves as a transceiver. The connection between the function module 4 and the detector 3 is preferably again via a wireless communication channel 3.4 namely a short-range radio link. Connection in this context means both the exchange of data between the function module 4 and the detector 3 as well as the energy supply of the detector 3 via one of the functional module 4 generated electromagnetic field. The functional module 4 includes for this purpose a functional module 4.3 , which serves as a transceiver for short ranges and for this purpose with the function module 3.3 the detector 3 communicated. For a cable connection between the function module 2 and the functional module 4 can the functional module 4 expedient also from the functional module 2 be energized. If the functional module 4 over a wireless communication channel 2.4 with the function module 2 is connected, is expediently an autonomous power supply for the function module 4 intended. This includes the function module 4 a functional module 4.2 , which is preferably a power supply unit. The operation of this embodiment of a hazard detection system 1 corresponds substantially to the operation of the first embodiment described above, with the difference that is due to the interposition of the functional module 4 between the functional module 2 and the detector 3 results. The exchange of data between the function module 2 and the detector 3 , in particular when querying the state of the detector 3 , Lower integration of the function module 4 , which practically serves as a relay station. The wireless power supply of the detector 3 is done by the function module 4 , The use of functional modules 4 advantageously allows monitoring of extended objects.

Claims (13)

Alarm system ( 1 ) with a function module functioning as a central ( 2 ) and with at least one detector remote from the control center ( 3 ), characterized in that the detector ( 3 ) is powered by the center wirelessly. Alarm system ( 1 ) according to claim 1, characterized in that the functional module ( 2 ) a device (functional module 2.1 ) for the generation of an electromagnetic field, that the detector ( 3 ) a device (functional module 3.3 ) for receiving the from the functional module ( 2 ) and that the detector ( 3 ) a memory device ( 21 ), which is supplied from the electromagnetic field derived energy. Alarm system ( 1 ) according to one of the preceding claims, characterized in that the devices provided for the generation or the reception of the electromagnetic field are also used for the transmission of data between the functional module ( 2 ) and the detector ( 3 ) are provided. Alarm system ( 1 ) according to one of the preceding claims, characterized in that it is a bidirectional data transmission. Alarm system ( 1 ) according to one of the preceding claims, characterized in that a functional module ( 4 ), which is functionally connected between the functional module ( 2 ) and the detector ( 3 ) is switched. Alarm system ( 1 ) according to one of the preceding claims, characterized in that the detector ( 3 ) from the functional module ( 4 ) is energized. Alarm system ( 1 ) according to one of the preceding claims, characterized in that the functional module ( 4 ) locally from the functional module ( 2 ) is discontinued. Alarm system ( 1 ) according to one of the preceding claims, characterized in that one of the hazard warning system ( 1 ) is subdivided into monitoring units and that for each monitoring unit a functional module ( 4 ) is provided. Alarm system ( 1 ) according to one of the preceding claims, characterized in that each functional module ( 4 ) a plurality of detectors ( 3 ) assigned. Alarm system ( 1 ) according to one of the preceding claims, characterized in that a for the power supply of a detector ( 3 ) constructed electromagnetic field is constantly maintained. Alarm system ( 1 ) according to one of the preceding claims, characterized in that a for the power supply of a detector ( 3 ) in each case until the complete charging of the memory device ( 21 ) and then shut down. Alarm system ( 1 ) according to one of the preceding claims, characterized in that the electromagnetic field for the power supply of the detector ( 3 ) in each case in connection with or shortly before a status inquiry of a detector ( 3 ) is activated. Detector of a security alarm system ( 1 ), preferably a hazard alarm system ( 1 ) according to any one of the preceding claims, characterized in that the detector is designed such that it from a locally remote, functioning as a central function module ( 2 ) is powered by wireless means.